2021
Suppression of Kv3.3 channels by antisense oligonucleotides reverses biochemical effects and motor impairment in spinocerebellar ataxia type 13 mice
Zhang Y, Quraishi IH, McClure H, Williams LA, Cheng Y, Kale S, Dempsey GT, Agrawal S, Gerber DJ, McManus OB, Kaczmarek LK. Suppression of Kv3.3 channels by antisense oligonucleotides reverses biochemical effects and motor impairment in spinocerebellar ataxia type 13 mice. The FASEB Journal 2021, 35: e22053. PMID: 34820911, PMCID: PMC8630780, DOI: 10.1096/fj.202101356r.Peer-Reviewed Original ResearchConceptsHAX-1Wild-type animalsMultivesicular bodiesKv3.3 channelsLate endosomes/multivesicular bodiesTank Binding Kinase 1Type animalsCell survival proteinsDisease-causing mutationsVoltage-dependent potassium channelsSpinocerebellar ataxia type 13Survival proteinsKinase 1Mature intact animalsTBK1 activationAge-matched wild-type animalsLevels of CD63Progressive cerebellar degenerationWild-type miceMutationsProtein levelsMutant micePotassium channelsDependent potassium channelsType mice
2020
Impaired motor skill learning and altered seizure susceptibility in mice with loss or gain of function of the Kcnt1 gene encoding Slack (KNa1.1) Na+-activated K+ channels
Quraishi IH, Mercier MR, McClure H, Couture RL, Schwartz ML, Lukowski R, Ruth P, Kaczmarek LK. Impaired motor skill learning and altered seizure susceptibility in mice with loss or gain of function of the Kcnt1 gene encoding Slack (KNa1.1) Na+-activated K+ channels. Scientific Reports 2020, 10: 3213. PMID: 32081855, PMCID: PMC7035262, DOI: 10.1038/s41598-020-60028-z.Peer-Reviewed Original ResearchConceptsMaximum electroshock-induced seizuresEpilepsy of infancyPentylenetetrazole-induced seizuresVideo-EEG monitoringElectroshock-induced seizuresForms of epilepsyWild-type miceSlack channelsImpaired motor skillsProcedural motor learningMotor skillsWild-type animalsSevere intellectual disabilityOpen-field behaviorCortical seizuresKCNT1 geneSpontaneous seizuresFocal seizuresSeizure susceptibilitySeizure activityType miceMouse modelAnimal modelsInterictal spikesSeizures
2013
Expression of Kv1.3 potassium channels regulates density of cortical interneurons
Duque A, Gazula V, Kaczmarek LK. Expression of Kv1.3 potassium channels regulates density of cortical interneurons. Developmental Neurobiology 2013, 73: 841-855. PMID: 23821603, PMCID: PMC3829632, DOI: 10.1002/dneu.22105.Peer-Reviewed Original ResearchConceptsKv1.3 geneMembrane-spanning channelsKv1.3-/- miceVasoactive intestinal peptideEffect of deletionCerebral cortexKv1.3 potassium channelsNeuropeptide YNeuronal differentiationKv1.3 proteinOlfactory bulbInterneuron populationsSelective poresExpression of Kv1.3Large familyCell membraneKv channelsNumber of calbindinNormal cortical functionWhole cerebral cortexWild-type miceKv1.3GenesDetection of odorsPotassium channels
2010
Kv1.3 is the exclusive voltage‐gated K+ channel of platelets and megakaryocytes: roles in membrane potential, Ca2+ signalling and platelet count
McCloskey C, Jones S, Amisten S, Snowden RT, Kaczmarek LK, Erlinge D, Goodall AH, Forsythe ID, Mahaut‐Smith M. Kv1.3 is the exclusive voltage‐gated K+ channel of platelets and megakaryocytes: roles in membrane potential, Ca2+ signalling and platelet count. The Journal Of Physiology 2010, 588: 1399-1406. PMID: 20308249, PMCID: PMC2876798, DOI: 10.1113/jphysiol.2010.188136.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBlood PlateletsCalcium SignalingCell SizeDNA, ComplementaryHumansIn Vitro TechniquesKv1.3 Potassium ChannelMegakaryocytesMembrane PotentialsMiceMice, Inbred C57BLPatch-Clamp TechniquesPlatelet CountReverse Transcriptase Polymerase Chain ReactionScorpion VenomsSecond Messenger SystemsConceptsLarge ionic conductanceMembrane potentialHuman plateletsKv alphaMegakaryocyte developmentAncillary subunitsQuantitative RT-PCRMolecular levelKv channelsRole of Kv1.3MegakaryocytesKv1.3RT-PCRWild-type miceKv currentsSubunitsSignalingMiceApoptosisMargatoxinPlatelet activationRoleIonic conductancesPlateletsActivation
2004
Kv1.3 Channel Gene-Targeted Deletion Produces “Super-Smeller Mice” with Altered Glomeruli, Interacting Scaffolding Proteins, and Biophysics
Fadool DA, Tucker K, Perkins R, Fasciani G, Thompson RN, Parsons AD, Overton JM, Koni PA, Flavell RA, Kaczmarek LK. Kv1.3 Channel Gene-Targeted Deletion Produces “Super-Smeller Mice” with Altered Glomeruli, Interacting Scaffolding Proteins, and Biophysics. Neuron 2004, 41: 389-404. PMID: 14766178, PMCID: PMC2737549, DOI: 10.1016/s0896-6273(03)00844-4.Peer-Reviewed Original ResearchMeSH Keywords14-3-3 ProteinsAdaptor Proteins, Vesicular TransportAnimalsBehavior, AnimalBlotting, WesternBody WeightBrain-Derived Neurotrophic FactorCalcium ChannelsCells, CulturedDensitometryDifferential ThresholdDiscrimination, PsychologicalDose-Response Relationship, DrugDrinkingElectric StimulationEmbryo, MammalianEnergy IntakeExploratory BehaviorGene DeletionGRB10 Adaptor ProteinHabituation, PsychophysiologicHumansInsulinKidneyKineticsKv1.3 Potassium ChannelMembrane PotentialsMiceMice, KnockoutMotor ActivityNerve Tissue ProteinsNeuronsNeurotoxinsNuclear Matrix-Associated ProteinsOdorantsOlfactory BulbPatch-Clamp TechniquesPotassium ChannelsPotassium Channels, Voltage-GatedProteinsRas ProteinsReceptor, trkBReverse Transcriptase Polymerase Chain ReactionRNA, MessengerScorpion VenomsSensory ThresholdsSrc-Family KinasesTime FactorsTyrosine 3-MonooxygenaseConceptsKv1.3-/- miceProtein-protein interactionsGene-targeted deletionKv1.3-null miceSignal transductionScaffolding proteinSignaling cascadesChannel genesC-type inactivationDeletionMembrane potentialNull miceOlfactory codingDetection of odorsPotassium channelsKv1.3 channelsProteinSense of smellSlow inactivation kineticsWild-type miceTransductionGenesOlfactory bulb mitral cellsMiceRole